R Cellular interactions in prostate cancer genesis and dissemination.

Romanian Journal of Morphology and Embryology 2010, 51(3):427–435
REVIEW
Cellular interactions in prostate
cancer genesis and dissemination.
Looking beyond the obvious
C. TOMULEASA1), G. KACSÓ2), OLGA SORIŢĂU1), S. ŞUŞMAN3),
A. IRIMIE4), PIROSKA VIRÁG1)
1)
Department of Cancer Immunology
Department of Radiation Oncology
2)
“Ion Chiricuţă” Comprehensive Cancer Center, Cluj-Napoca
3)
Department of Histology,
“Iuliu Haţieganu” University of Medicine and Pharmacy, Cluj-Napoca
4)
Department of Surgery,
“Ion Chiricuţă” Comprehensive Cancer Center, Cluj-Napoca
Abstract
Similar to normal organs arising from normal stem cells, cancers can be viewed as organs composed of heterogeneous cellular
populations arising from cancer cells with indefinite proliferation abilities. The continuous malignant progression is maintained by the
proliferation of cancer stem cells and not the progeny that undergo limited proliferation before terminally differentiating. Effective therapy
must eradicate malignant cells with unlimited clonogenic expansion within the primary tumor bulk. Thus, resolving both the specific cell of
origin for prostate cancer and the interactions between the cells and the surrounding microenvironment within the cancer stem cell niche
are crucial to appropriately define rational targets for therapeutic intervention and cure prostate cancer.
Keywords: prostate cancer stem cells, stem cell niche, cell plasticity.
Epidemiology and current management
Prostate cancer is one of the most commonly
diagnosed cancers and the second leading cause of
cancer-related death in European and American men,
with approximately 220 000 new cases of prostate
cancer and 30 000 deaths estimated to arise in the US
alone in 2010 [1, 2]. The increase in absolute incidence
can be ascribed to the combination of an aging male
population and the use of early testing, based on more
sophisticated measurement of serum levels for not only
prostate-specific antigen (PSA), but also newer serum
based markers such as PCA3 [3], and general proteomic
markers [4].
Organ confined, low PSA (under 10 ng/mL) and low
Gleason score (GS<7) prostate cancer can be managed
effectively by radical surgical intervention, radiotherapy
or even active monitoring, but the prognosis for patients
with high-Gleason grade tumors detected either by
screening or incidentally as a result of urinary tract
symptoms remains bleak. In this case, most patients are
cured by local-regional treatment in which radiotherapy
has a prominent role and is used either alone or with
hormonal treatment [5]. In metastatic disease, mainly in
bones, the androgen-modulation therapy results in
immediate and rapid decrease in pain and undetectable
levels of PSA [6], but approximately 30–40% of
prostate cancer patients reveal failure after treatment
and the time to death remains stubbornly consistent,
even with improved regimens of chemotherapy [7, 8].
Research strategies have focused on refining the
delivery of radical therapies using laparoscopic or
robotic surgery and intensity-modulated radiation
therapy, which have met little success to reduce toxicity
because treatment aimed at the whole gland results in
damage to surrounding structures such as bladder neck,
neurovascular bundles, external bladder sphincter,
sigmoid or rectum. The answer to developing a more
biologically adapted treatment might therefore be found
in the specific architecture of the prostate epithelium
and its patterning during ontogenic development and
oncogenesis.
Stem cells in embryology and pathology
The prostate is a small, walnut shaped and sized
gland, located below the bladder. It surrounds the
urethra and has a fibromuscular function which acts to
restrict urine flow, but its main function is to produce
essential proteins for the functioning of sperm, such as
acid phosphatase, citric acid and bioavailable zinc.
It also produces some of the highest amounts of
polyamines, which regulate the pH of sperm and
preserves a mildly alkaline environment for the sperm
within the acidic female cervix [9].
The human prostate develops from the urogenital
sinus in response to testosterone stimulation and initially consists of a multilayered epithelium surrounded
by mesenchyma. During ductal budding, which starts at
10 weeks of gestation, multiple epithelial outgrowths
428
C. Tomuleasa et al.
invade the mesenchyma and form ducts that elongate
and branch out from the urethra, terminating into acini
[10]. From the 20th weeks of gestation up to puberty, the
immature prostatic acini and ducts are lined with
multiple layers of progenitor cells, with round nuclei
and scant cytoplasm. Postnatal development includes
periods of growth during the first year and during
puberty because of testosterone surge, separated by a
period of quiescence during childhood. After having
received androgen stimulation, the immature multilayered epithelium differentiates into a two-layered epithelium consisting of peripheral flattened to cuboidal basal
cells and inner secretory cylindrical epithelial cells [11].
Both the epithelial and stromal components of the
adult prostate cell structure express the receptor for
testosteron, called the androgen receptor (AR). In the
absence of AR, the prostate cannot develop and shrinks
or involutes after castration, but will regenerate after
restoration of normal androgen levels. The castration
resistant fraction of normal prostate epithelium, called
prostate epithelial stem cells, has been proposed to
reside within the basal epithelial compartment by
Collins AT and Maitland NJ [12], but the key stimulus
for regrowth lies within the key AR.
Secretory cells typically express high levels of AR,
prostate specific antigen (PSA) and low molecular
weight keratins (CK8 and CK18). In contrast, basal cells
show either low or undetectable levels of AR, expressing high molecular keratins (CK5, CK14 and CK34β
E12) and the basal cell marker p63 [13]. The progenitor
cells are phenotypically intermediate between basal and
secretory cells and represent the transient amplifying
cell population, expressing CK19. Using an immunocytochemical approach, Wang Y et al. [14] have
demonstrated that most cells in the urogenital sinus coexpress secretory and basal cell markers, as well as
CK19, CD133, α2β1 or Sca-1. These data proposed the
idea that the intermediate double positive basal cell
population represents prostate stem cells, able to differentiate into both mature secretory and basal cells.
A third type of cells, neuroendocrine cells are scarce
and express chromogranin A and synaptophysin but
lack PSA and AR and induce proliferation of adjacent
cells through paracrine secretion of neuropeptides, as
proposed by Bonkhoff H et al. [15] (Figure 1).
Figure 1 – The basic histology of the prostate gland.
With regards to prostate cancer, it has remained a
long-standing conundrum that prostate carcinoma is
effectively diagnosed by a complete absence of basal
cells [16], whereas prostate epithelial stem cells have
been thought to reside in the basal layer. Prostate
adenocarcinoma usually proceeds through a series of
defined stages, from prostatic intraepithelial neoplasia
(PIN), to prostatic cancer in situ, to invasive and
metastatic cancer. Tumor cells are usually AR+ and
PSA+, mimicking ontogenesis, and initially respond to
androgen depletion. After a remission of up to several
years, cancer will become resistant to therapy and
eventually progress despite low levels of androgen and
chemoradiotherapy. Most investigators link prostate
carcinogenesis to the “cancer stem cell model”, which
explains most symptoms and pathology examinations.
Cancer stem cells and resistance to
conventional therapy
As therapy-resistant, prostate cancer is the second
most common cause of cancer death in men, there is an
urgent need for the development of alternative targeted
therapies. The most compelling evidence of the existence of prostate stem cells in the basal cell compartment
is derived from the mouse castration model, where
androgen withdrawal results in glandular involution and
apoptosis in more than 90% of epithelial cells, but leaves
the basal cell layer intact [17]. As slow-cycling cellsretaining bromodeoxyuridine (BrdU) labeling following
androgen withdrawal or replacement experiments have
been identified in both basal and luminal cell compartments, Tsujimura A et al. imply that prostate stem cells
are not restricted to one epithelial cell layer [18].
It is possible that cancer arises in a cell at any stage
of differentiation, from the most primitive stem cells to
the most differentiated tissue-specific cell. Early events
are most likely to occur in normal stem cells, as only
these cells live long enough to accumulate the several
genetic changes required for an invasive cancer to
develop. Once one or more initiating genetic changes
have occurred in the progenitor, all the downstream
cells will contain this change, in which case it is
possible that one of the daughter cells acquire not only
the properties of a stem cell, but also the additional
genetic changes that allows the cancer to progress to the
next step and invade the surrounding tissues.
Cancer stem cells (CSC) were first isolated in acute
myeloid leukemia as CD34+ CD38-- cells, and after just
a few years, from solid tumors, including hepatocellular
carcinoma and brain cancer [19, 20]. Prostate cancer
stem cells were also isolated by a variety of methods,
including isolation of the “side population” based on the
exclusion of different dyes, on their ability to form
tumor spheres (prostatospheres) under serum-free nonattachment conditions and on the basis of CD44,
CD133, Sca-1, CD49f or integrin α2β1 surface marker
expression [21–23].
Current therapies are not yet curative as CSC may
escape through both increased efflux of chemotherapeutic agents due to the ABCB1 (MDR, P-gp) and
ABCG2 cell membrane proteins, and through increased
DNA-repair. Several proteins of the ABC transporter
superfamily are overexpressed by stem cells and make
up the so-called “side population”, having the capability
for accelerated efflux from the cells of fluorescent dyes
Hoechst 33342 and Rhodamine 123, transported by
the very same ABC family proteins [24, 25]. Metastatic
Cellular interactions in prostate cancer genesis and dissemination. Looking beyond the obvious
prostate cancer may be treated with androgen deprivation therapy by either surgical castration or medical
castration with gonadotropin-releasing hormone agonists.
The AR is expressed in almost all prostate adenocarcinoma cells and dictates the response to therapy.
The initial response is transient and the tumor will
progress to castrate-resistant prostate cancer because
of AR gene amplification resulting in reactivation
of androgen-responsive genes involved in growth and
survival [26].
Radiotherapy plays and important role in the management of prostate carcinoma, but the radioresistance
of tumor cells limits the outcome of ionizing radiation.
The developed resistance is related to global changes in
expression of proteins interfering with various intracellular pathways. Such is the case of over-expressed
pre-mRNA-processing factor 19 (PRPF19) and programmed cell death 6-interacting protein (PDCD6IP)
that reduce the levels of apoptosis in cells exposed to
stress or DNA-damaging factors [27]. Other changes in
the proteomic profile, such as up-regulation of glyceraldehyde-3-phosphate (GAPDH) or phospho-glycerate
kinase 1 (PGK1), also influence cancer cell aggressiveness and the capacity for invasion and metastasis formation, being implicated in the behavior of other types
of cancer as well (as PGK1, that influences HER-2/neu
signaling in breast cancer) [28].
Because it is much easier to kill downstream cells
than CSC, we may explain why the vast majority of
metastatic cancers respond for relatively short periods to
drugs or hormonal therapy, until the stem cell’ pool
recovers and resumes its inexorable growth.
429
inducible factor-1 (HIF-1). Under hypoxic conditions
(3–5% O2), gene expression may be altered toward an
immature phenotype, promoting de-dedifferentiation of
prostate tumour cells into more “stem-like” ones. This
hypothesis has recently been confirmed by a neuroblastoma cell line [30]. The hypoxic cells expressed
higher levels of the embryonic stem-ness gene OCT-4
due to the interactions between HIF-transcription factors
(HIF-1α and HIF-2α). OCT-4 is a direct target of
HIF-2α, the induction of whom could contribute to the
formation and maintenance of cancer stem cells.
Hypoxia also modulates the activity of Notch signaling,
as well as Wnt by the down-regulation of E-cadherin,
which leads to increased levels of β-catenin, a Wnt
intracellular messenger. Also, both HIF-α subunits
control the activity of the well-known oncogene c-Myc
through the antagonization of its activity. It competes
for binding with the c-Myc partner Sp-1, resulting in
cell cycle arrest at low O2 levels [31]. These observations may have a significant role in cell signaling
within prostate neoplasia containing regions of hypoxia,
considering the multiple properties of the Myc protein.
It should also be pointed out that Myc and OCT-4 were
two of the four genes shown to be capable of inducing
fibroblasts to revert to a stem cell phenotype [32].
The stem cell niche
An important consideration for cancerogenesis is the
influence of tissue microenvironment, which has a deep
effect on the behavior of cells in a tumor and their
ability to metastasize. It is well known that in vivo cell–
cell and cell–matrix interactions play an important role
in how different cells respond to specific stimuli. In a
normal tissue, these interactions are critical in cell
function and are important for the concept of “stem cell
niche”. The niche is a cell environment that provides
critical stem cell maintenance signals to support the
undifferentiated phenotype of progenitor cells. Such
relevant signals include the Hedgehog, Wnt or Notch
pathways, all of them important in early ontogenesis
and control of cell differentiation and proliferation.
In cancer, the cell-cell and cell-matrix interactions are
overlaid on top of other features of tumor physiopathology microenvironment, including the presence of
hypoxia, low pH and nutrient deprivation. Fluctuations
of these parameters have profound effects on the
activity of cancer stem cells and their potential niche.
Hypoxia is an important feature of the niche because
is intrinsically linked to the formation of neovasculature, regulating the production of proangiogenic factors.
According to Hill RP et al. [29], 1% to 1.5% of the
genome is transcriptionally regulated by hypoxia
and many of these genes are controlled by hypoxia-
Figure 2 – A model for prostate oncogenesis. The
normal epithelium (under oxidative stress, Wnt
down-regulation or human gammaretrovirus Xenotrophic MuLV-related virus XMRV infection) will
have an increased proliferative potential and eventually lead to the appearance of the prostate intraepithelial neoplasia (PIN). The high proliferative
potential and telomerase activation determines the
evolution from PIN to invasive, metastatic and
treatment-resistant carcinoma.
Inflammation is a common occurrence in the human
prostate and is emerging as a strong candidate for the
primary etiological event of the tumor. The origin of the
inflammatory infiltrates can be related to infectious
agents or chemical damage [33]. Since the results of
zur Hausen in cervical epithelial cancer viral infection
plays a very important role in urogenital malignant
progression. A number of potentially carcinogenic viruses have been detected in human prostatic tissues, such
430
C. Tomuleasa et al.
as the oncogenic human papovavirus BK or the human
gammaretrovirus Xenotrophic MuLV-related virus
(XMRV) in premalignant lesions [34, 35]. These ideas
have improved the hypothesis of prostate oncogenesis,
where PIN is preceded by an inflammatory atrophy with
prostatic epithelial cells showing an increased Ki-67marked proliferation (Figure 2).
Zipori suggests that stem-ness could be “a transient
and reversible trait that almost any cell can assume
given the correct trigger (niche) and that is characterized
by having many potential outcomes but no specialization” [36]. Even if in his article, he refers to normal
stem multi-lineage differentiation, it raises the hypothesis that the same normal stem cells, circulating into
the blood stream and guided by chemokine signaling,
may interact with differentiated cells from a “metastatic
niche” that provides appropriate stimuli (i.e., hypoxia or
chronic inflammation due to infection) for de-differentiation or cell fusion. Can this be the birth of the
prostate cancer stem cell?
Cell behavior and plasticity
In the extrinsic pathways, it remains uncertain
whether hypoxia or chronic inflammation is enough for
carcinogenesis, but these factors are certainly the main
triggers. Inflammatory cells and mediators can destabilize the cell genome by inducing DNA-damage or
affecting the cell cycle checkpoints and repair systems.
Genetic instability, through accelerated somatic evolutions, leads to a genomically heterogeneous population
of expanding cells selected for their ability to proliferate, invade distant tissues and evade host defense.
Inflammation affects first of all the mismatch repair
(MMR) family members, whose mutation or epigenetic
silencing is associated with microsatellite instability.
Microsatellite instability show increased rates of DNAreplication errors throughout the genome, affecting
especially genes that contain in their coding regions
microsatellites intrinsically unstable and therefore prone
to be copied incorrectly during replication. MMR is
downregulated by a variety of mechanisms (including
HIF-1α, TNF or IL-1β) and leads to chromosomal instability, that in turn results in abnormal segregation of
chromosomes and aneuploidy [37, 38]. Chromosomal
instability is also associated with both inactivation of
p53 that normally protects cells from transformation by
inducing apoptosis upon DNA-damage, and with matrix
metalloproteinase dysregulation that act as oncogenes in
this case.
Bone marrow-derived mesenchymal stem cells do
not only constitute only the hematopoietic microenvironment, but are also responsible for the regeneration of
most tissues from the human body because of their
capacity to give rise to multiple mesenchymal lineage
cells and even endodermal or ectodermal lineage cells.
Because chronic inflammation can destabilize a cell’s
differentiation program, it is possible that prostate cancer
may emerge as a consequence of the interplay between
the microenvironment already prone for oncogenesis
and the plasticity of a circulating normal stem cell,
attracted to this inflammation site in the first place
through chemotaxis. This is a highly controversial point
of view that was already confirmed by Houghton J et al.
in gastric cancer. Her team proved that chronic gastric
inflammation consecutive to Helicobacter pylori infection, who leads over time to repetitive injury and repair
resulting in hyperproliferation and increased rate of
mitotic error, is linked to homing and engraftment in
peripheral tissue by bone marrow-derived stem cells.
These cells posses a very high degree of plasticity and
their signals for cell growth and differentiation are
unexpectedly sensitive. Thus, gastric cancer may originnate from bone marrow-derived cells [39].
We have established that the differentiation status of
a tumor cell is determined by the expression of a large
number of genes and their products and that the cell is
in close contact with it’s surrounding microenvironment, which can secrete a large amount of growth
factors and cytokines, in order to regulate the complex
biology of tumor cells. The niche is known to accelerate
the differentiation of cells, to sustain cells in G0 state
for long periods of time or to induce apoptosis and also
recently emerging data have proven that the tumor
microenvironment may down-regulate specific markers,
changing a previous phenotype. The extrinsic signals
may enhance the cell’s drug resistance and promote its
longevity, causing it even to de-differentiate into a
cancer stem cell. This theory has also been confirmed
by Dezorella N et al. in a multiple myeloma model,
proving that mesenchymal stromal cells can revert a
myeloma cell to a less differentiated state by the combined effects of interleukin-6 and extracellular matrix
interactions [40].
As unconventional the two theories mentioned
above might be, a true breakthrough in fundamental
oncology is the idea that clinically significant cancer
evolves from transient mutated or aneuploid neoplasia
by cell fusion to form unstable syncytia. Viruses, recently
detected in human prostatic tissues, induce the host cell
to express adhesion molecules that effects joining the
cytoplasms of two cells. Then viral Bcl-2 or over-expressed cellular Bcl-2 prevents the syncytia from undergoing p53-dependent apoptosis or p53-independent
death through mitotic catastrophe and as a direct result,
new aneuploid cells survive. Virus-catalyzed cell fusion
of tumor cells with normal cells in adjacent tissues
appears to be a pathway to invasion of the normal tissue
by the tumor [41].
The stated hypothesis is demonstrated by Human
Papilloma Virus (HPV), the etiological agent for cervical cancer. HPV-infection begins by engaging in cell-tocell transmission resulting in many stable binuclear
syncytia observed in low-grade squamous intraepithelial
lesions. Chromosomal aberrations then accumulate in
polyploid cells leading to high-grade squamous intraepithelial lesions [42].
The result of the fusion and tumor growth is prevented physiologically by the attachment of cells to the
intercellular matrix through the help of binding to
different components of the matrix such as hyaluronic
acid with different surface adhesion molecules, such as
CD44. Usually, this system does the job, but sometimes
the arrangement may be disrupted. One way is the
Cellular interactions in prostate cancer genesis and dissemination. Looking beyond the obvious
hyperglycosylation of glycoproteins like CD44 to an
extent that they cannot bind to the matrix. The intervention of other ligands, facilitated by polyamines
such as putresceine, spermidine or spermine, may
affects the normal tissue architecture and last but
equally as important, the surface adhesion molecules
can be cleaved and broken down such as cells are no
longer held in place. The last process appears to be
facilitated by over-expression of matrix metalloproteinases and proteins with a disintegrin and metalloproteinase domain (ADAMs) [43].
The recent association between human pathogens
and prostate cell plasticity, leading either to dedifferentiation, transdifferentiation or even to cell fusion, raise
possibilities of undiscovered functions and therapeutics
targeting the cancer stem cell niche for intraprostatic
cancers.
The circulating CSC – early metastatic
site interplay
Through clonal proliferation, a prostate CSC originating in the primary lesion and dispersed into circulation
will arrest in the capillary bed of distant organs, which
provides either pro or anti-metastatic stimuli regulating
the onset of distant colonization by the tumor cell. If the
surrounding environment is just right, this moment
marks the turning point from a localized, potentially
curable disease, to a system disorder. The progression of
prostate cancer is not random, but a highly orchestrated,
multi-step process, governed by basic cancer immunology. Once a clone capable of metastazing is formed,
the complex network of events leading to distant tumor
formation is still a matter of debate between two main
theories despite all recent breakthroughs in fundamental
oncology. This debate started when James Ewing
challenged Stephen Paget’s ‘seed and soil’ concept in
the early 1930’s [44, 45], but both hypothesis are not
mutually exclusive.
Once having left the primary tumor, the prostatospheres (binded prostate CSC) are subjected to intense
mechanical stress by shear forces caused by blood flow.
These tumor spheres soon disintegrate into solitary
prostate CSC in narrow capillaries, including the microvasculature of contracting skeletal and heart muscles
where the cells require sphere-to-cylinder shape transformation [46]. The lack of high plasticity is lethal to
the majority of tumor cells. Nevertheless, this is just the
first step of the Darwinian selection of the cells capable
of disseminating. The organization and structure of
cytoskeletal components such as actin can be modified
by external forces and since integrins appear to be
directly involved in the early steps of metastasis, cell
signaling and regulatory processes modulate their affinity may influence CSC adhesion or migration into host
organs [47]. As circulating tumor cells are usually adhesion-dependent, anoikis limits the available circulation
time and the cells’ resistance to this special form of
apoptosis. Thus, the most effective way for CSC is the
establishment of adhesive interactions within metastatic
target organs via the integrin–cadherin interplay.
431
Pathology examinations of target organ microvasculature often show tumor cells closely associated with
platelets, as well as leukocytes or the coagulation system
because specific adhesive systems provide selective
mechanisms for these interactions. The altered surface
glycosylation is a common feature of carcinoma cells,
including prostate adenocarcinoma, with high expression of sialyl Lewisa/x as selectin ligands is association
with poor prognosis in various cancers [48, 49] suggesting a potential role of such cell adhesion molecules in
the process of metastasis. The aggregation of platelets
around CSC may also involve thrombin and fibrin,
but in experimental settings, platelet inhibition reduces
the number of metastatic lesions and does not affect
organ distribution of size of metastatic foci. Borsig L
et al. report that the anti-metastatic effect of platelet
inhibition using heparin is limited to the initial five
hours after tumor cell inoculation [50], which indicates
that platelets are able to interfere with early events of
organ colonization.
The role of platelets in the metastatic network is not,
however, limited to pro-adhesive processes as aggregating platelets and fibrin meshworks can form a potent
shield around CSC that seems to prevent the contact
with Natural Killer (NK) cells. In addition, for arrest in
the capillary bed of target organs, prostate CSC may be
associated with polymorphonuclear neutrophils (PMN)
to enhance the colonization capacity. This is possible
because of the expression of inter-cellular adhesion
molecule-1 (ICAM-1), that enables tumor cells to adhere
to PMN during their presence in the blood stream.
If CSC were to interact with NK cells, programmed cell
death would be induced by the perforin/granizyme pathway following granule exocytosis or by the Fas/Fas-L
pathway within a few hours [51].
The CSC–endothelial cell interactions are equally as
important as the previous step. Because blood vessels
are generally lined with endothelial cells, circulating
CSC are similar to leukocytes in using endothelial cell
specific adhesion molecules, such as selectins or ICAMs
to interact the same endothelial cells before they touch
the underlying basement membrane in the course of
extravasation. Endothelial cell surface molecules play a
role in organ specific settlement of prostate CSC and the
inhibition of tumor cell adhesion by anti-TF (Thomsen–
Friedenreich factor) results in increased survival without
impairing tumor cell proliferation, in a mouse model for
spontaneous breast cancer metastasis [52].
CSC may also induce apoptosis of endothelial cells
or increase their E-selectin surface expression, facilitating further the adhesion to the endothelium. The last,
but not least of the major interactions a cancer stem
cells must overcome to colonize a distant organ is that
with the extracellular matrix (ECM). Among the most
important molecules are again the integrins, the expression of whom may be altered in comparison with
normal tissue cells. Certain integrins, such as α5β1 [53],
can change the growth behavior, neoangiogenesis and
anchorage independent survival of normal cells and act
as oncogenes or tumor suppressor genes. Integrins interfere with metastasis through their dual role in impaired
cell adhesion at the primary site and by allowing tumor-
432
C. Tomuleasa et al.
initiating cells to settle in tissue with an ECM composition different to their home tissue [54].
As CSC posses an altered expression of cell adhesion molecules and the stromal ECM of metastatic sites
differ from one of the primary tumour or from that of
normal tissues, the adhesive interactions are particularly
sensitive in prostate cancer dissemination. Additionally,
soluble matrix proteins, such as osteopontin, hyaluronectin or sialoprotein may also influence these interactions. The stroma also contains various paracrine factors,
such as growth factors, cytokines or hormones that act
with ECM components and regulate the metastatic niche
availability in a very specific manner for each type of
primary neoplasia [55–57]. Such is the case of prostate
circulating stem cells, where the bone marrow derived
ECM molecule osteonectin acts chemotactically for
the primary tumor cells. Prostate adenocarcinoma will
therefore disseminate preferentially to bones.
The mechanism for preferential dissemination of
prostate tumor cells is more complex and it involves
CXC chemokine interplay. The homeostatic chemokine
stromal cell-derived factor-1 (CXCL12/SDF-1) regulates
development, stem cell motility, neoangiogenesis and
tumorigenesis. It binds to the widely expressed cell
surface receptor CXCR4 and the involvement of this
receptor–ligand interaction in the directed migration of
cancer cells to metastatic sites has been proven not only
in prostate adenocarcinoma, but also in breast, lung,
ovarian, renal or brain tumors [58]. Up-regulated by
HIF-1α or VEGF, CXCR4 receptor blocking using
monoclonal antibodies should inhibit tumor growth and
metastasis in head and neck cancers, primary brain
tumors or acute lymphoblastic leukemia, apart from
urology malignancies.
Targeting prostate cancer stem cells
It is well known that cancer stem cells are immortal
due to the telomerase enzyme hTERT. Telomerase is
present in all prostate cancers and has a very high
activity. One small molecule shown to inhibit hTERT
in vitro and in vivo is RHPS4, shown to stabilize the
four-stranded G-quadruplex structure formed by the
tracts of G-rich single-stranded DNA at the telomeres.
Another promising agent with similar effects is the
phosphoramidate oligonucleotide GRN163L, targeting
the telomerase active site and inhibits binding to telomeres in CD44hi and CD133+ cells [59, 60]. Phosphate
and tension homolog (PTEN) is a lipid phosphatase
known to play a vital role in the proliferation, motility,
survival and metabolism of cells and interacts with
many signaling pathways, including p53, Akt/PI3K and
mTOR. In prostate neoplasia, the loss of PTEN occurs
in 30–50% of cases and re-expression in various cell
lines results in apoptosis. Re-expression is achieved by
inhibition of PI3K with wortmannin and LY294002,
but these compounds have broad specificity and have
not been employed in the clinical setting [61].
The Wnt/β-catenin pathway controls self-renewal
and proliferation of CSC, the members of the Wnt being
generally secreted by other cells of the niche and bind to
the seven transmembrane receptor Frizzled. Targeted
molecular therapy is difficult to perform because of
the high complexity of the pathway. Wnt antibodies
proven to induce apoptosis are currently being developed in non-small cell lung carcinoma, melanoma and
mesothelioma [62], but no results have been published
prostate cancers.
Hedgehog (HH) signaling is a highly conserved
developmental pathway and orchestrates body patterning, contributing to stem cell maintenance. HH is activated by three soluble molecules (Indian, Sonic and
Desert) that act as paracrine or autocrine signals before
binding to Patched (PTCH) receptors and in this way
activating the transmembrane protein Smoothened
(SMO). SMO triggers translocation of GLI1 and GLI2
(Glioma Associated Homolog) transcription signals
to the nucleus and thus modulates cell proliferation,
epithelial-to-mesenchymal transition or angiogenesis.
During ductal morphogenesis, Sonic HH is expressed in
sites of active epithelial growth and the loss of GLI1/2
function results in impaired ductal budding and stem
cell depletion. HH is more active in prostate cancer
in comparison with normal or hyperplastic tissue and
PTCH and GLI expression is dramatically increased in
metastatic lesion in comparison with primary tumors.
The best-known HH inhibitor is Cyclopamine, that
targets SMO and is shown to downregulate drug transporter expression in castration-resistant cancer, enhancing chemotherapy [63]. Cyclopamine drives androgenindependent growth in prostate cancer, synergistic with
ErbB, but its employment in the clinic is impaired by
low oral bioavailability and poor pharmacokinetics.
A better pharmacokinetic profile has been shown by
GDC-0449, a SMO-antagonist currently in phase II
clinical trials for ovarian and colorectal carcinoma,
as well as basal cell carcinoma. This molecule has also
shown outstanding results in the treatment of medulloblastoma [64].
Another important pathway in the stem cell conundrum is Notch signaling, that regulates cell fate determination. Notch proteins are heterodimeric receptors
that interact with the surface ligands Delta, Delta-like
and Jagged from an adjacent cell. This bind will release
the intracellular Notch domain through proteolysis by
ADAMs and γ-secretase/presenilin. The effects will be
either oncogenic or tumor-suppressor. Notch is necessary in prostate development for the proper branching
morphogenesis and in the differentiation of the prostate
following castration and androgen replacement [65],
in the same time regulating the activity of CK8+ CK14+
transit-amplifying cells. The best Notch inhibitors are the
gamma secretase molecules, which prevent the release
of the intracellular Notch domain by inhibiting its
cleavage. Such substances, like DAPT or MK0752 are
currently under phase I clinical trial investigation
for CD34+CD38- CSC in acute lymphoblastic leukemia
and CD133+ CSC in central nervous system malignancies [66].
Plerixafor, also known as AMD3100, is a bicyclam
molecule, which binds reversibly to CXCR4. Even
though initially developed as a potential therapeutic
agent against HIV, preclinical data have shown that
AMD3100 blocks CXCL12 binding of CXCR4 and as a
Cellular interactions in prostate cancer genesis and dissemination. Looking beyond the obvious
result it inhibits SDF-1α-induced calcium flux and
chemotaxis. Clinical trials have demonstrated that
Plerixafor is effective for the mobilization of peripheral
blood stem cells for use in autologous hematopoietic
stem cell transplantation, but blocking the same
CXCR4–CXCL12 axis can also play an important role
in the control of CSC dissemination from the primary
prostate lesion and metastasis. New drugs such as
CTCE-9908 are currently undergoing preclinical confirmation in this setting [67].
The current view of prostate cancer is that of a
complex disease caused by genomic and epigenetic
aberrations that affect a defined set of cellular properties. Yet a primary cause of several cancers, accounting
for about one-fifth of all cancer causes in the world, is a
defined virus, bacterium or some other unknown element that may alter the normal physiology of a cell to
such extent that it changes beyond control. Although the
prostate cancer stem cell model is only at its early stage
of development, this hypothesis is crucial for the understanding of prostate carcinogenesis as well as for assessing successes and failures of future early treatment
using targeted molecular agents.
References
[1] SCHRÖDER FH, HUGOSSON J, ROOBOL MJ, TAMMELA TL,
CIATTO S, NELEN V, KWIATKOWSKI M, LUJAN M, LILJA H,
ZAPPA M, DENIS LJ, RECKER F, BERENGUER A, MÄÄTTÄNEN L,
BANGMA CH, AUS G, VILLERS A, REBILLARD X, VAN DER
KWAST T, BLIJENBERG BG, MOSS SM, DE KONING HJ,
AUVINEN A; ERSPC INVESTIGATORS, Screening and
prostate-cancer mortality in a randomized European study,
N Engl J Med, 2009, 360(13):1320–1328.
[2] ANDRIOLE GL, CRAWFORD ED, GRUBB RL 3RD, BUYS SS,
CHIA D, CHURCH TR, FOUAD MN, GELMANN EP, KVALE PA,
REDING DJ, WEISSFELD JL, YOKOCHI LA, O'BRIEN B,
CLAPP JD, RATHMELL JM, RILEY TL, HAYES RB, KRAMER BS,
IZMIRLIAN G, MILLER AB, PINSKY PF, PROROK PC,
GOHAGAN JK, BERG CD; PLCO PROJECT TEAM, Mortality
results from a randomized prostate-cancer screening trial,
N Engl J Med, 2009, 360(13):1310–1319.
[3] HESSELS D, KLEIN GUNNEWIEK JM, VAN OORT I, KARTHAUS HF,
VAN LEENDERS GJ, VAN BALKEN B, KIEMENEY LA, WITJES JA,
SCHALKEN JA, DD3(PCA3)-based molecular urine analysis
for the diagnosis of prostate cancer, Eur Urol, 2003,
44(1):8–15.
[4] ORNSTEIN DK, RAYFORD W, FUSARO VA, CONRADS TP,
ROSS SJ, HITT BA, WIGGINS WW, VEENSTRA TD, LIOTTA LA,
PETRICOIN EF 3RD, Serum proteomic profiling can discriminate prostate cancer from benign prostates in men with
total prostate specific antigen levels between 2.5 and 15.0
ng/ml, J Urol, 2004, 172(4 Pt 1):1302–1305.
[5] THOMPSON I, THRASHER JB, AUS G, BURNETT AL, CANBYHAGINO ED, COOKSON MS, D'AMICO AV, DMOCHOWSKI RR,
ETON DT, FORMAN JD, GOLDENBERG SL, HERNANDEZ J,
HIGANO CS, KRAUS SR, MOUL JW, TANGEN CM; AUA
PROSTATE CANCER CLINICAL GUIDELINE UPDATE PANEL,
Guidelines for the management of clinically localized prostate cancer: 2007 update, J Urol, 2007, 177(6):2106–2131.
[6] ROCCHI P, SO A, KOJIMA S, SIGNAEVSKY M, BERALDI E,
FAZLI L, HURTADO-COLL A, YAMANAKA K, GLEAVE M,
Heat shock protein 27 increases after androgen ablation
and plays a cytoprotective role in hormone-refractary
prostate cancer, Cancer Res, 2004, 64(18):6595–6602.
[7] TANNOCK IF, DE WIT R, BERRY WR, HORTI J, PLUZANSKA A,
CHI KN, OUDARD S, THÉODORE C, JAMES ND, TURESSON I,
ROSENTHAL MA, EISENBERGER MA; TAX 327 INVESTIGATORS,
Docetaxel plus prednisone or mitoxantrone plus prednisone
for advanced prostate cancer, N Engl J Med, 2004,
351(15):1502–1512.
433
[8] SOUHAMI L, BAE K, PILEPICH M, SANDLER H, Impact of the
duration of adjuvant hormonal therapy in patients with
locally advanced prostate cancer treated with radiotherapy:
a secondary analysis of RTOG 85–31, J Clin Oncol, 2009,
27(13):2137–2143.
[9] DEVENS BH, WEEKS RS, BURNS MR, CARLSON CL,
MK,
Polyamine
depletion
therapy
in
BRAWER
prostate cancer, Prostate Cancer Prostatic Dis, 2000,
3(4):275–279.
[10] SHEN MM, WANG X, ECONOMIDES KD, WALKER D, ABATESHEN C, Progenitor cells for the prostate epithelium: roles in
development, regeneration, and cancer, Cold Spring Harb
Symp Quant Biol, 2008, 73:529–538.
[11] TIMMS BG, MOHS TJ, DIDIO LJ, Ductal budding and
branching patterns in the developing prostate, J Urol, 1994,
151(5):1427–1432.
[12] COLLINS AT, MAITLAND NJ, Prostate cancer stem cells, Eur J
Cancer, 2006, 42(9):1213–1218.
[13] NIKITIN AY, MATOSO A, ROY-BURMAN P, Prostate stem cells
and cancer, Histol Histopathol, 2007, 22(9):1043–1049.
[14] WANG Y, HAYWARD S, CAO M, THAYER K, CUNHA G, Cell
differentiation lineage in the prostate, Differentiation, 2001,
68(4–5):270–279.
[15] BONKHOFF H, WERNERT N, DHOM G, REMBERGER K, Relation
of endocrine-paracrine cells to cell proliferation in normal,
hyperplastic, and neoplastic human prostate, Prostate,
1991, 19(2):91–98.
nd
[16] SKARIN AT (ed), Atlas of diagnostic oncology, 2 edition,
Mosby–Wolfe, London, 1996, 465–552.
[17] DE MARZO AM, MEEKER AK, EPSTEIN JI, COFFEY DS,
Prostate stem cell compartments: expression of the cell
cycle inhibitor p27Kip1 in normal, hyperplastic, and neoplastic cells, Am J Pathol, 1998, 153(3):911–919.
[18] TSUJIMURA A, KOIKAWA Y, SALM S, TAKAO T, COETZEE S,
MOSCATELLI D, SHAPIRO E, LEPOR H, SUN TT, WILSON EL,
Proximal location of mouse prostate epithelial stem
cells: a model of prostatic homeostasis, J Cell Biol, 2002,
157(7):1257–1265.
[19] TOMULEASA C, SORITAU O, RUS-CIUCA D, POP T, TODEA D,
MOSTEANU O, PINTEA B, FORIS V, SUSMAN S, KACSO G,
IRIMIE A, Isolation and characterization of hepatic cancer
cells with stem-like properties from hepatocellular carcinoma, J Gastrointestin Liv Dis, 2010, 19(1):61–67.
[20] TOMULEASA C, SORIŢĂU O, RUS-CIUCĂ D, FORIS V, IOANI H,
ŞUŞMAN S, PETRESCU M, MIHU C, CERNEA D, FLORIAN IST,
KACSÓ G, IRIMIE AL, Functional and molecular characterization of glioblastoma multiforme-derived brain cancer stem
cells, J BUON, 2010, in press.
[21] COLLINS AT, BERRY PA, HYDE C, STOWER MJ, MAITLAND NJ,
Prospective identification of tumorigenic prostate cancer
stem cells, Cancer Res, 2005, 65(23):10946–10951.
[22] GU G, YUAN J, WILLS M, KASPER S, Prostate cancer
cells with stem cell characteristics reconstitute the
original human tumor in vivo, Cancer Res, 2007,
67(10):4807–4815.
[23] HONORIO S, LI H, TANG DG, Prostate cancer stem/
progenitor cells. In: BAGLEY RG, TEICHER BA (eds), Stem
cells and cancer, Springer Science, New York, 2009,
217–231.
[24] SKVORTSOVA I, SKVORTSOV S, STASYK T, RAJU U,
POPPER BA, SCHIESTL B, VON GUGGENBERG E, NEHER A,
BONN GK, HUBER LA, LUKAS P, Intracellular signaling
pathways regulating radioresistance of human prostate
carcinoma cells, Proteomics, 2008, 8(21):4521–4533.
[25] STAVROVSKAYA AA, STROMSKAYA TP, Transport proteins of
the ABC family and multidrug resistance of tumor cells,
Biochemistry (Mosc), 2008, 73(5):592–604.
[26] ATTARD G, SWENNENHUIS JF, OLMOS D, REID AH, VICKERS E,
A'HERN R, LEVINK R, COUMANS F, MOREIRA J, RIISNAES R,
OOMMEN NB, HAWCHE G, JAMESON C, THOMPSON E,
SIPKEMA R, CARDEN CP, PARKER C, DEARNALEY D, KAYE SB,
COOPER CS, MOLINA A, COX ME, TERSTAPPEN LW,
DE BONO JS, Characterization of ERG, AR and PTEN
gene status in circulating tumor cells from patients with
castration-resistant prostate cancer, Cancer Res, 2009,
69(7):2912–2918.
434
C. Tomuleasa et al.
[27] LU X, LEGERSKI RJ, The Prp19/Pso4 core complex
undergoes ubiquitylation and structural alterations in
response to DNA damage, Biochem Biophys Res Commun,
2007, 354(4):968–974.
[28] ZHANG D, TAI LK, WONG LL, CHIU LL, SETHI SK, KOAY ES,
Proteomic study reveals that proteins involved in metabolic
and detoxification pathways are highly expressed in
HER-2/neu-positive breast cancer, Mol Cell Proteomics,
2005, 4(11):1686–1696.
[29] HILL RP, MARIE-EGYPTIENNE DT, HEDLEY DW, Cancer stem
cells, hypoxia and metastasis, Semin Radiat Oncol, 2009,
19(2):106–111.
[30] DAS B, TSUCHIDA R, MALKIN D, KOREN G, BARUCHEL S,
YEGER H, Hypoxia enhances tumor stemness by increasing
the invasive and tumorigenic side population fraction, Stem
Cells, 2008, 26(7):1818–1830.
[31] KOSHIJI M, KAGEYAMA Y, PETE EA, HORIKAWA I,
BARRETT JC, HUANG LE, HIF-1α induces cell cycle arrest
by functionally counteracting Myc, EMBO J, 2004,
23(9):1949–1956.
[32] MAHERALI N, SHRIDHARAN R, XIE W, UTIKAL J, EMINLI S,
ARNOLD K, STADTFELD M, YACHECHKO R, TCHIEU J,
JAENISCH R, PLATH K, HOCHEDLINGER K, Directly reprogrammed fibroblasts show global epigenetic remodeling
and widespread tissue contribution, Cell Stem Cell, 2007,
1(1):55–70.
[33] ELKAHWAJI JE, ZHONG W, HOPKINS WJ, BUSHMAN W,
Chronic bacterial infection and inflammation incite reactive
hyperplasia in a mouse model of chronic prostatitis,
Prostate, 2006, 67(1):14–21.
[34] DAS D, WOJNO K, IMPERIALE MJ, BK virus as a cofactor in
the etiology of prostate cancer in its early stages, J Virol,
2008, 82(6):2705–2714.
[35] URISMAN A, MOLINARO RJ, FISCHER N, PLUMMER SJ,
CASEY G, KLEIN EA, MALATHI K, MAGI-GALLUZZI C,
TUBBS RR, GANEM D, SILVERMAN RH, DERISI JL, Identification of a novel Gammaretrovirus in prostate tumors of
patients homozygous for R462Q RNASEL variant, PloS
Pathog, 2006, 2(3):e25.
[36] ZIPORI D, The nature of stem cells: state rather than entity,
Nat Rev Genet, 2004, 5(11):873–878.
[37] DUELLI DM, PADILLA-NASH HM, BERMAN D, MURPHY KM,
RIED T, LAZEBNIK Y, A virus causes cancer by inducing
massive chromosomal instability through cell fusion, Curr
Biol, 2007, 17(5):431–437.
[38] COLOTTA F, ALLAVENA P, SICA A, GARLANDA C, MANTOVANI A,
Cancer-related inflammation, the seventh hallmark of
cancer: links to genetic instability, Carcinogenesis, 2009,
30(7):1073–1081.
[39] HOUGHTON J, STOICOV C, NOMURA S, ROGERS AB,
CARLSON J, LI H, CAI X, FOX JG, GOLDENRING JR, WANG TC,
Gastric cancer originating from bone-marrow derived cells,
Science, 2004, 306(5701):1568–1571.
[40] DEZORELLA N, PEVSNER-FISCHER M, DEUTSCH V, KAY S,
BARON S, STERN R, TAVOR S, NAGLER A, NAPARSTEK E,
ZIPORI D, KATZ BZ, Mesenchymal stromal cells revert
multiple myeloma cells to less differentiated phenotype by
the combined activities of adhesive interactions and
interleukin-6, Exp Cell Res, 2009, 315(11):1904–1913.
[41] DITTMAR T, NAGLER C, SCHWITALLA S, REITH G,
NIGGEMANN B, ZÄNKER KS, Recurrence cancer stem
cells – made by cell fusion?, Med Hypotheses, 2009,
73(4):542–547.
[42] GRACE VM, SHALINI JV, IEKHA TT, DEVARAJ SN, DEVARAJ H,
Co-overexpression of p53 and bcl-2 proteins in HPVinduced squamous cell carcinoma of the uterine cervix,
Gynecol Oncol, 2003, 91(1):51–58.
[43] PARRIS G, The cell clone ecology hypothesis and the
cell fusion model of cancer progression and metastasis
(II): three pathways for spontaneous cell–cell fusion and
escape from the intercellular matrix, Med Hypotheses,
2006, 67(1):172–176.
[44] PAGET S, The distribution of secondary growths in cancer of
the breast, Lancet, 1889, 1:571–573.
th
[45] EWING J, Neoplastic diseases, 6 edition, WB Saunders,
Philadelphia, 1928.
[46] HAIER J, NICOLSON GL, Tumor cell adhesion under
hydrodynamic conditions of fluid flow, APMIS, 2001,
109(4):241–262.
[47] ENNS A, GASSMANN P, SCHLÜTER K, KORB T, SPIEGEL HU,
SENNINGER N, HAIER J, Integrins can directly mediate
metastatic tumor cell adhesion within the liver sinusoids,
J Gastrointest Surg, 2004, 8(8):1049–1059; discussion 1060.
[48] NAKAMORI S, KAMEYAMA M, IMAOKA S, FURUKAWA H,
ISHIKAWA O, SASAKI Y, KABUTO T, IWANAGA T,
MATSUSHITA Y, IRIMURA T, Increased expression of sialyl
Lewisx antigen correlates with poor survival in patients with
colorectal carcinoma: clinicopathological and immunohistochemical study, Cancer Res, 1993, 53(15):3632–3637.
[49] AMADO M, CARNEIRO F, SEIXAS M, CLAUSEN H, SOBRINHOSIMÕES M, Dimeric sialyl-Le(x) expression in gastric
carcinoma correlates with venous invasion and poor
outcome, Gastroenterology, 1998, 114(3):462–470.
[50] BORSIG L, WONG R, HYNES RO, VARKI NM, VARKI A,
Synergistic effects of L- and P-selectin in facilitating tumor
metastasis can involve non-mucin ligands and implicate
leukocytes as enhancers of metastasis, Proc Natl Acad Sci
U S A, 2002, 99(4):2193–2198.
[51] JIANG H, CHESS L, Regulation of immune response by
T cells, N Engl J Med, 2006, 354(11):1166–1176.
[52] HEIMBURG J, YAN J, MOREY S, GLINSKII OV, HUXLEY VH,
WILD L, KLICK R, ROY R, GLINSKY VV, RITTENHOUSEOLSON K, Inhibition of spontaneous breast cancer metastasis by anti-Thomsen–Friedenreich antigen monoclonal
antibody JAA–F11, Neoplasia, 2006, 8(11):939–948.
[53] MBEUNKUI F, JOHANN DJ JR, Cancer and the tumor microenvironment: a review of an essential relationship, Cancer
Chemother Pharmacol, 2009, 63(4):571–582.
[54] GASSMANN P, HAIER J, The tumor cell-host organ interface
in the early onset of metastatic organ colonisation, Clin Exp
Metastasis, 2008, 25(2):171–181.
[55] HAYASHI C, RITTLING S, HAYATA T, AMAGASA T, DENHARDT D,
EZURA Y, NAKASHIMA K, NODA M, Serum osteopontin,
an enhancer of tumor metastasis to bone, promotes
B16 melanoma cell migration, J Cell Biochem, 2007,
101(4):979–986.
[56] DESAI B, ROGERS MJ, CHELLAIAH MA, Mechanisms of
osteopontin and CD44 as metastatic principles in prostate
cancer cells, Mol Cancer, 2007, 6:18.
[57] HYNES RO, The extracellular matrix: not just pretty fibrils,
Science, 2009, 326(5957):1216–1219.
[58] VANDERCAPPELLEN J, VAN DAMME J, STRUYF S, The role of
CXC chemokines and their receptors in cancer, Cancer
Lett, 2008, 267(2):226–244.
[59] PHATAK P, COOKSON JC, DAI F, SMITH V, GARTENHAUS RB,
STEVENS MF, BURGER AM, Telomere uncapping by the
G-quadruplex ligand RHPS4 inhibits clonogenic tumour cell
growth in vitro and in vivo consistent with a cancer stem cell
targeting mechanism, Br J Cancer, 2007, 96(8):1223–1233.
[60] DIKMEN ZG, GELLERT GC, JACKSON S, GRYAZNOV S,
TRESSLER R, DOGAN P, WRIGHT WE, SHAY JW, In vivo
inhibition of lung cancer by GRN163L: a novel human
telomerase inhibitor, Cancer Res, 2005, 65(17):7866–7873.
[61] DUBROVSKA A, KIM S, SALAMONE RJ, WALKER JR, MAIRA SM,
GARCÍA-ECHEVERRÍA C, SCHULTZ PG, REDDY VA, The role of
PTEN/Akt/PI3K signaling in the maintenance and viability of
prostate cancer stem-like cell populations, Proc Natl Acad
Sci U S A, 2009, 106(1):268–273.
[62] YOU L, HE B, XU Z, UEMATSU K, MAZIERES J, MIKAMI I,
REGUART N, MOODY TW, KITAJEWSKI J, MCCORMICK F,
JABLONS DM, Inhibition of Wnt-2-mediated signaling
induces programmed cell death in non-small-cell lung
cancer cells, Oncogene, 2004, 23(36):6170–6174.
[63] TREMBLAY MR, NESLER M, WHEATHERHEAD R, CASTRO AC,
Recent patents for Hedgehog pathway inhibitors for
the treatment of malignancy, Expert Opin Ther Pat, 2009,
19(8):1039–1056.
[64] RUDIN CM, HANN CL, LATERRA J, YAUCH RL, CALLAHAN CA,
FU L, HOLCOMB T, STINSON J, GOULD SE, COLEMAN B,
LORUSSO PM, VON HOFF DD, DE SAUVAGE FJ, LOW JA,
Treatment of medulloblastoma with hedgehog pathway inhibitor GDC-0449, N Engl J Med, 2009, 361(12):1173–1178.
Cellular interactions in prostate cancer genesis and dissemination. Looking beyond the obvious
[65] CREA F, MATHEWS LA, FARRAR WL, HURT EM, Targeting
prostate cancer stem cells, Anticancer Agents Med Chem,
2009, 9(10):1105–1113.
[66] BESANÇON R, VALSESIA-WITTMANN S, PUISIEUX A,
DE FROMENTEL CC, MAGUER-SATTA V, Cancer stem cells:
the emerging challenge of drug targeting, Curr Med Chem,
2009, 16(4):394–416.
435
[67] PORVASNIK S, SAKAMOTO N, KUSMARTSEV S, ERUSLANOV E,
KIM WJ, CAO W, URBANEK C, WONG D, GOODISON S,
ROSSER CJ, Effects of CXCR4 antagonist CTCE-9908 on
prostate tumor growth, Prostate, 2009, 69(13):1460–1469.
Corresponding authors
Ciprian Tomuleasa, Department of Cancer Immunology, “Ion Chiricuţă” Comprehensive Cancer Center, 34–36
Republicii Street, 400015 Cluj-Napoca, Romania; Phone +40741–337 480, e-mail: [email protected]
Gabriel Kacsó, MD, PhD, Assistant Professor of Oncology and Radiotherapy, “Iuliu Haţieganu” University of
Medicine and Pharmacy, 8 Victor Babeş Street, 400023 Cluj-Napoca, Romania; e-mail: [email protected]
Received: May 15th, 2010
Accepted: August 5th, 2010